Channel Bonding With Multiple Network Types

ABSTRACT

Different data communication architectures deliver a wide variety of content, including audio and video content, to consumers. The architectures employ channel bonding to deliver more bandwidth than any single communication channel can carry. In some implementations, different network types may be channel bonded to function as a single logical channel.

1. CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of non-provisional application Ser. No. 13/673,302, filed Nov. 9, 2012, entitled “Channel Bonding With Multiple Network Types”, and claims the benefit of and incorporates by reference: U.S. Provisional Application Ser. No. 61/663,878, filed Jun. 25, 2012, entitled “Channel Bonding-Audio-Visual Broadcast” and Provisional Application Ser. No. 61/609,339, filed Mar. 11, 2012, entitled “Method and Apparatus for Using Multiple Physical Channels for Audio-Video Broadcasting and Multicasting.”

2. TECHNICAL FIELD

This disclosure relates to audio and video communication techniques. In particular, this disclosure relates to channel bonding for channels with different network types.

3. BACKGROUND

Rapid advances in electronics and communication technologies, driven by immense private and public sector demand, have resulted in the widespread adoption of smart phones, personal computers, internet ready televisions and media players, and many other devices in every part of society, whether in homes, in business, or in government. These devices have the potential to consume significant amounts of audio and video content. At the same time, data networks have been developed that attempt to deliver the content to the devices in many different ways. Further improvements in the delivery of content to the devices will help continue to drive demand for not only the devices, but for the content delivery services that feed the devices.

BRIEF DESCRIPTION OF THE DRAWINGS

The innovation may be better understood with reference to the following drawings and description. In the figures, like reference numerals designate corresponding parts throughout the different views.

FIG. 1 shows an example of a content delivery architecture that employs channel bonding.

FIG. 2 shows an example of logic for content delivery using channel bonding.

FIG. 3 shows an example of a content delivery architecture that employs channel bonding.

FIG. 4 shows an example of logic for content delivery using channel bonding.

FIG. 5 shows a timing example.

FIG. 6 shows an example of a content delivery architecture that employs channel bonding.

FIG. 7 shows an example of logic for content delivery using channel bonding.

FIG. 8 shows an example implementation of a distributor.

FIG. 9 shows an example implementation of a collator.

FIG. 10 shows an example of a content delivery architecture that performs channel bonding below the transport layer, e.g., at the data-link layer.

FIG. 11 shows an example of channel bonding at the data-link layer.

FIG. 12 shows an example of channel bonding at the data-link layer.

FIG. 13 shows an example of logic that a data-link layer may implement for channel bonding at the data-link layer.

FIG. 14 shows an example of logic that a data-link layer may implement for channel debonding at the data-link layer.

FIG. 15 shows an example variant of the content delivery architecture of FIG. 6.

FIG. 16 shows an example variant of the content delivery architecture of FIG. 7.

FIG. 17 graph illustrating characteristics of different network types with regard to performance and availability.

FIG. 18 is a schematic illustrating a system channel bonding across two different network types.

FIG. 19 is an illustration of different logical layers that may be used for channel bonding.

FIG. 20 is a flow chart illustrating a method for adaptively changing channel bonding characteristic.

FIG. 21 is a schematic illustrating an in-home network configured to channel bond different network types.

FIG. 22 is a schematic illustrating a device for in-home network configured to channel bond different network types.

DETAILED DESCRIPTION

FIG. 1 shows an example content delivery architecture 100. The architecture 100 delivers data (e.g., audio streams and video programs) from a source 102 to a destination 104. The source 102 may include satellite, cable, or other media providers, and may represent, for example, a head-end distribution center that delivers content to consumers. The source 102 may receive the data in the form of Motion Picture Expert Group 2 (MPEG2) Transport Stream (TS) packets 128, when the data is audio/visual programming, for example. The destination 104 may be a home, business, or other location, where, for example, a set top box processes the data sent by and received from the source 102.

The source 102 may include a statistical multiplexer 106 and a distributor 108. The statistical multiplexer 106 helps make data transmission efficient by reducing idle time in the source transport stream (STS) 110. In that regard, the statistical multiplexer 106 may interleave data from multiple input sources together to form the transport stream 110. For example, the statistical multiplexer 106 may allocate additional STS 110 bandwidth among high bit rate program channels and relatively less bandwidth among low bit rate program channels to provide the bandwidth needed to convey widely varying types of content at varying bit rates to the destination 104 at any desired quality level. Thus, the statistical multiplexer 106 very flexibly divides the bandwidth of the STS 110 among any number of input sources.

Several input sources are present in FIG. 1: Source 1, Source 2, . . . , Source n. There may be any number of such input sources carrying any type of audio, video, or other type of data (e.g., web pages or file transfer data). Specific examples of source data include MPEG or MPEG2 TS packets for digital television (e.g., individual television programs or stations), and 4K×2K High Efficiency Video Coding (HVEC) video (e.g., H.265/MPEG-H) data, but the input sources may provide any type of input data. The source data (e.g., the MPEG 2 packets) may include program identifiers (PIDs) that indicate a specific program (e.g., which television station) to which the data in the packets belongs.

The STS 110 may have a data rate that exceeds the transport capability of any one or more communication links between the source 102 and the destination 104. For example, the STS 110 data rate may exceed the data rate supported by a particular cable communication channel exiting the source 102. To help deliver the aggregate bandwidth of the STS 110 to the destination 104, the source 102 includes a distributor 108 and modulators 130 that feed a bonded channel group 112 of multiple individual communication channels. In other words, the source 102 distributes the aggregate bandwidth of the STS 110 across multiple outgoing communication channels that form a bonded channel group 112, and that together provide the bandwidth for communicating the data in the STS 110 to the destination 104.

The distributor 108 may be implemented in hardware, software, or both. The distributor 108 may determine which data in the STS 110 to send on which communication channel. As will be explained in more detail below, the distributor 108 may divide the STS 110 into chunks of one or more packets. The chunks may vary in size over time, based on the communication channel that will carry the chunk, the program content in the chunk, or based on any other desired chunk decision factors implemented in the distributor 108. The distributor 108 may forward any particular chunk to the modulator for the channel that the distributor 108 has decided will convey that particular chunk to the destination 104.

In that regard, the multiple individual communication channels within the bonded channel group 112 provide an aggregate amount of bandwidth, which may be less than, equal to, or in excess of the aggregate bandwidth of the STS 110. As just one example, there may be three 30 Mbs physical cable channels running from the source 102 to the destination 104 that handle, in the aggregate, up to 90 Mbs. The communication channels in the bonded channel group 112 may be any type of communication channel, including dial-up (e.g., 56 Kbps) channels, ADSL or ADSL 2 channels, coaxial cable channels, wireless channels such as 802.11a/b/g/n channels or 60 GHz WiGig channels, Cable TV channels, WiMAX/IEEE 802.16 channels, Fiber optic, 10 Base T, 100 Base T, 1000 Base T, power lines, or other types of communication channels.

The bonded channel group 112 travels to the destination 104 over any number of transport mechanisms 114 suitable for the communication channels within the bonded channel group 112. The transport mechanisms 144 may include physical cabling (e.g., fiber optic or cable TV cabling), wireless connections (e.g., satellite, microwave connections, 802.11 a/b/g/n connections), or any combination of such connections.

At the destination 104, the bonded channel group 112 is input into individual channel demodulators 116. The channel demodulators 116 recover the data sent by the source 102 in each communication channel. A collator 118 collects the data recovered by the demodulators 116, and may create a destination transport stream (DTS) 120. The DTS 120 may be one or more streams of packets recovered from the individual communication channels as sequenced by the collator 118.

The destination 104 also includes a transport inbound processor (TIP) 122. The TIP 122 processes the DTS 120. For example, the TIP 122 may execute program identifier (PID) filtering for each channel independently of other channels. To that end, the TIP 122 may identify, select, and output packets from a selected program (e.g., a selected program ‘j’) that are present in the DTS 120, and drop or discard packets for other programs. In the example shown in FIG. 1, the TIP 122 has recovered program ‘j’, which corresponds to the program originally provided by Source 1. The TIP 122 provides the recovered program to any desired endpoints 124, such as televisions, laptops, mobile phones, and personal computers. The destination 104 may be a set top box, for example, and some or all of the demodulators 116, collator 118, and TIP 122 may be implemented as hardware, software, or both in the set top box.

The source 102 and the destination 104 may exchange configuration communications 126. The configuration communications 126 may travel over an out-of-band or in-band channel between the source 102 and the destination 104, for example in the same or a similar way as program channel guide information, and using any of the communication channel types identified above. One example of a configuration communication is a message from the source 102 to the destination 104 that conveys the parameters of the bonded channel group 112 to the destination 104. More specifically, the configuration communication 126 may specify the number of communication channels bonded together; identifiers of the bonded communication channels; the types of programs that the bonded communication channels will carry; marker packet format; chunk, program packet, or marker packet size; chunk, program packet, or marker packet PID or sequence number information, or any other chunk or bonding configuration information that facilitates processing of the bonded channel group 112 at the destination 104. One example of a configuration communication message from the destination 104 to the source 102 is a configuration communication that specifies the number of communication channels that the destination 104 may process as eligible bonded channels; identifiers of the eligible bonded channels; status information concerning status of the demodulators 116, e.g., that a demodulator is not functioning and that its corresponding communication channel should not be included in a bonded channel group; channel conditions that affect bit rate or bandwidth; or any other information that the source 102 and the distributor 108 may consider that affects processing of the data from the sources into a bonded channel group.

FIG. 2 shows an example of logic 200 for content delivery using channel bonding that the architecture 100 described above may implement in hardware, software, or both. Additional detailed examples are provided below, particularly with regard to marker packets and other options.

In FIG. 2, input sources receive program data (202). The program data may be received from any content provider, and may include any desired audio, visual, or data content, including cable television programming, streaming music, file transfer data, as just three examples. The input sources provide the program data to the statistical multiplexer 106 (204), which multiplexes the program data to generate the source transport stream (STS) 110 (206).

The source 102 provides the STS 110 to the distributor 108 (208). The distributor 108 reads bonding configuration parameters (210). The bonding configuration parameters may specify the number of communication channels in the bonded channel group 112, the communication channels that may be included in the bonded channel group 112, the type of communication channels that may be included in the bonding channel group 112, the program sources eligible for bonding, when and for how long communication channels and program sources are available for channel bonding, bonding adaptation criteria, and any other parameters that may influence how and when the distributor 108 pushes program data across the communication channels in the bonded channel group 112. The distributor 108 sends the program data to the communication channels in the bonded channel group 112 (212). Specific examples of how the distributor 108 accomplishes this are provided below. The source 102 thereby communicates program data to the destination 104 across the multiple communication channels in the bonded channel group 112 (214).

At the destination 104, the demodulators 116 receive the program data over the communication channels (218). The demodulators 116 provide the recovered program data (optionally after buffering) to the collator 118. The collator 118 analyzes group information, sequence information, PIDs, and any other desired information obtained from the data packets arriving on the communication channels and creates a destination transport stream (DTS) 120 from the recovered program data (220). The DTS 120 may convey the program packets in the same sequence as the STS 110, for example.

The collator 118 provides the DTS 120 to the TIP 122 (222). The TIP 122 reads data selection parameters (224). The data selection parameters may specify, for example, which audio/visual program is desired, and may be obtained from viewer input, from automated selection programs or processes (e.g., in a digital video recorder), or in other ways. Accordingly, the TIP 122 filters the DTS 120 to recover the program packets that match the data selection parameters (e.g., by PID filtering) (226). The TIP 122 thereby generates a content output that includes an output packet stream for the selected program. The TIP 122 delivers the generated content to any desired device 124 that consumes the content, such as televisions, smart phones, personal computers, or any other device.

Several channel bonding processing options are discussed next. Some options make reference to marker packets (MPs) inserted into the data streams going to the destination 104 over the communication channels. The marker packets may be MPEG2 TS packets, for example, with an identifier that flags them as MPs. In the first option, the distributor 108 adds marker packets on a per-channel basis, for example in a round-robin manner. In the second option, the distributor 108 generates and adds markers on a per-chunk basis, for example in a round-robin manner at chunk boundaries. In the third option, when packets from the same program will be routed to multiple communication channels, each packet receives a program ID and a sequence ID, and no marker packets are needed. In the fourth option, spare bits in network frames defined below the network layer, e.g., at the data-link layer, carry channel bonding information to the source 104.

Regarding the first option, FIG. 3 shows another example of a content delivery architecture 300 that employs channel bonding. In the architecture 300, a marker packet (MP) source 302 feeds MPs to the statistical multiplexer 106. The MP source 302 may provide marker packets at any frequency. For example, the MP source 302 may provide a marker packet for each communication channel in the bonded channel group 112 for every ‘n’ non-marker packets received from the sources, every ‘k’ ms, or at some other time or packet spacing frequency. The time or packet spacing, ‘n’ or ‘k’ may take any desired value, e.g., from n=1 packet to tens of thousands of packets, or k=1 ms to 1 second. In other implementations, the distributor 108 generates the MPs, rather than receiving them in the STS 110.

Fewer marker packets consume less channel bandwidth, leaving more room for program data. However, more marker packets increase the ability of the destination 104 to adapt to changes in the program data, including allowing the collator 108 to more quickly synchronize the multiple data streams across the bonded channel group 112, allowing faster program channel changes through the TIP 122, and facilitating faster adaptation to changes in the configuration of the bonded channel group 112. Marker packet insertion may vary depending on any desired parameters. Examples of such parameters include available buffer sizes; target, average, or worst case recovery time for recovering from transmission errors or other transmission issues; target program channel change latency or other types of latency; and target program frame size.

In FIG. 3, the distributor 108 pushes packets to the modulators 130 on a round-robin basis, starting with any desired modulator 130. More specifically, the distributor 108 may communicate packets on a round-robin basis to each communication channel in the bonded channel group 112, one packet at a time. In other implementations described below, the round-robin distribution may be done n-packets at a time, where ‘n’ is greater than 1. However, for the example shown in FIG. 3, the distributor 108 pushes one packet at a time in a round-robin manner across the communication channels that compose the bonded channel group 112. Accordingly, given the example STS 110 packet stream of {MP-0, MP-1, MP-2, 1-0, 1-1, 2-1, 2-2, n-0}, the distributor 108 pushes:

MP-0 to channel 1, MP-1 to channel 2, MP-2 to channel 3; then

pkt 1-0 to channel 1, pkt 1-1 to channel 2, pkt 2-1 to channel 3; then

pkt 2-2 to channel 1, pkt n-0 to channel 2, and so on.

The MP source 302 may provide MPs to the statistical multiplexer 106 at a selected priority level, such as a highest available priority level, or a higher priority level than any other packets arriving from the program sources. Furthermore, the number of MPs in a set of MPs may match the number of communication channels in the bonded channel group 112. For example, when there are seven (7) communication channels in the bonded channel group 112, the MP source 302 may provide seven highest priority MPs to the statistical multiplexer 106. The statistical multiplexer 106 may then output the high priority MPs immediately next in the STS 110, so that the group of seven MPs arrive in sequence at the distributor 108. As a result of the packet-by-packet round-robin distribution, one of each of the seven marker packets correctly is pushed to one of the seven communication channels in the bonded channel group 112 to flag a stream of program packets that follow each MP.

The statistical multiplexer 106 or the distributor 108 or the MP source 302 may give the MPs a special identifier, such as a unique PID (e.g., MARKER_PID) that flags the MPs as marker packets. Any other desired content may be present in the MPs. As examples, the MPs may include a channel number and group number. The channel number may identify the communication channel that sent that MP (e.g., channel 0, 1, or 2 for a bonded channel group 112 of three communication channels). The channel number provides a type of sequence number that identifies, the first, second, third, and so on, communication channel in sequence to which the distributor 108 has sent program packets. The channel number, in other words, identifies a bonded channel sequence of distribution of program packets to the communication channels in the bonded channel group.

The group number may identify which set of MPs any particular MP belongs to, and the source 102 may increment the group number with each new set of MPs (e.g., every three MPs when there are three communication channels in the bonded channel group 112). The group number may also facilitate packet alignment, when, for example, jitter or skew is larger than the gap between inserted packets.

Note that the distributor 108 need not have any special knowledge of the MPs. Instead, the distributor 108 may push packets on a round-robin basis to the communication channels, without knowing or understanding what types of packets it is sending. However, in other implementations, the distributor 108 may in fact analyze and manipulate the packets that it distributes, to insert or modify fields in the MPS, for example. Additionally, the distributor 108 may generate the MPs, rather than receiving them in the STS 110.

The destination 104 processes the marker packets, and may align packets in a fixed order from the demodulators 116 to form the DTS 120. The destination 104 may include First In First Out (FIFO) buffers 304, or other types of memory, to counter jitter/skew on the communication channels, and the resultant mis-alignment in reception of packets across the various communication channels. The FIFOs 304 may be part of the collator 118 or may be implemented separately. A FIFO may be provided for each communication channel, to provide a set of parallel buffers on the receive side, for example.

At the destination 104, the collator 118 may drop all packets before a MP from each channel is received. The collator 118 checks the group number of the marker packet in each channel, and drops packets until the collator 118 has found marker packets with matching group numbers on each communication channel. When the group numbers do not match, this may be an indicator to the collator 118 that the skew is larger than the gap between marker packets.

The channel number in the marker packets specifies the sequence of communication channels from which the collator 118 will obtain packets. The collator 118 obtains packets in a round-robin manner that matches the round-robin distribution at the source 102. In an example with three communication channels in the bonded channel group 112, the collator 118 may start by obtaining a packet from the communication channel carrying MP sequence number zero, then moving to the communication channel carrying MP sequence number one and obtaining a packet, then moving to the communication channel carrying MP sequence number two and obtaining a packet, then back to the sequence number zero communication channel in a round-robin manner. The collator 118 thereby produces a DTS 120 that corresponds to the STS 110. The TIP 122 may then extract the selected program from the DTS 120.

FIG. 4 shows an example of logic 400 for content delivery using channel bonding that may be implemented in hardware, software, or both in the example architecture 300 described above. Input sources receive program data (402), and in addition, a MP source 302 may provide MPs (404). The input sources and MP source provide the program data and the MPs to the statistical multiplexer 106 (406), which multiplexes the program data and MPs to generate the source transport stream (STS) 110 (408).

In particular, the MPs may have a high priority, so that the statistical multiplexer 106 inserts them into the STS 110 sequentially without gaps before other program data packets. The STS 110 is provided to the distributor 108 (410). The distributor 108 reads bonding configuration parameters (412). The bonding configuration parameters may specify that the distributor 108 should take the round-robin distribution approach, and may specify round-robin distribution parameters. Examples of such parameters include the round-robin distribution chunk size, e.g., ‘r’ packets at a time per communication channel (e.g., ‘r’=1), in what situations the distributor 108 should execute the round-robin technique, or any other round-robin parameter. As noted above, the bonding configuration parameters may also specify the number of communication channels in the bonding channel group 112, the communication channels that may be included in the bonding channel group 112, the type of communication channels that may be included in the bonding channel group 112, the program sources eligible for bonding, when and for how long communication channels and program sources are available for channel bonding, and any other parameters that may influence how the distributor 108 pushes program data across the communication channels in the bonded channel group 112.

The distributor 108 pushes the program data to the communication channels in the bonded channel group 112 (414). The source 102 thereby communicates program data to the destination 104 across the multiple communication channels in the bonded channel group 112 (416).

More particularly, the distributor 108 may push the program packets to the communication channels in round-robin manner. In one implementation, the round-robin approach is a one packet at a time approach. In other words, the distributor 108 may take each packet (when ‘r’=1) from the STS 110 and push it to the next communication channel in sequence. As such, the in-order sequence of MPs from the STS 110 is distributed one MP per communication channel, and is followed by one or more program packets. The MPs thereby effectively flag for the destination 104 the program packets that follow the MPs. After a predetermined number of program packets, the MP source provides another group of MPs that are then distributed across the communication channels, and the cycle repeats.

At the destination 104, the demodulators 116 receive the program data over the communication channels (420). The demodulators 116 provide the recovered program data to buffers (e.g., the FIFOs 304) to help address jitter/skew (422) on the communication channels. The buffered data is provided to the collator 118, which may pull packets from the buffers to synchronize on MPs. The collator 118 analyzes group information, sequence information, PIDs, and any other desired information obtained from the MPs and program packets to synchronize on MPs. The synchronization may include finding sequential MPs of the same group number across each communication channel in the bonded channel group 112. The collator 118 may then create a destination transport stream (DTS) 120 from the recovered program data (424) by adding packets to the DTS 120 in a round-robin manner across the communication channels in the bonded channel group 112, going in order specified by the channel numbers specified in the MPs. The DTS 120 may convey the program packets in the same sequence as the STS 110, for example.

The collator 118 provides the DTS 120 to the TIP 122 (426). The TIP 122 reads channel selection parameters (428). The channel selection parameters may specify, for example, which program is desired, and may be obtained from viewer input, from automated selection programs or processes (e.g., in a digital video recorder), or in other ways. Accordingly, the TIP 122 filters the DTS 120 to recover the program packets that match the channel selection parameters (e.g., by PID filtering) (430). The TIP 122 thereby generates a content output that includes an output packet stream for the selected program. The TIP 122 delivers the generated content to any desired device 124 that consumes the content, such as televisions, smart phones, personal computers, or any other device.

FIG. 5 shows a timing example 500 which shows that in some implementations, the source 102 may address transmit clock variations in the modulators 130. FIG. 5 shows transmit buffers 502, each of which may provide some predetermined depth, such as a depth at least that of the channel timing variation (e.g., 200 ms). As one example, the communication channels may be expected to have the same nominal payload rates, e.g., 38.71 Mb/s. Further, assume that the transmit clock in each modulator is independent, and can vary by plus or minus 200 ppm.

Thus, in the worst case, two channels in a bonded channel group may have a clock difference of 400 ppm. As shown in the example in FIG. 5, the timing different from channel 1 to channel 2 is 200 ppm, and the timing difference between channel 1 and channel ‘m’ is 400 ppm. The timing difference of 400 ppm may amount to as much as one 188 byte MPEG2 TS packet every 2500 outgoing packets.

Accordingly, the source 102 may insert a compensation packet (which may have NULL content) on channel ‘m’ every 2500 packets to cover the extra outgoing packet, and also insert a compensation packet on channel 2 every 5000 packets for the same reason. The compensation packet may appear, for example, just prior to the MP, or anywhere else in the outgoing data stream. The destination 104 may identify and discard compensation packets (or any other type of jitter/skew compensation packet).

The source 102 may implement a buffer feedback 504. The buffer feedback 504 informs the distributor 108 about buffer depths in the transmit buffers 502. When the buffers run empty, or at other times, the distributor 108 may insert compensation packets, e.g., before MPs.

FIG. 6 shows another example of a content delivery architecture 600 that employs channel bonding. In this second option, the architecture 600 includes a distributor 108 that sends data over the communication channels in communication units called chunks (but any other term may refer to the communication units). The chunks may include one or more packets from any of the program sources. For example, a chunk may be 1 packet, 10 packets, 100 packets, 27 packets, 10,000 packets, 100 ms of packets, 20 ms of packets, 30 ms of video data, 5 s of audio data, or any other number or timing of packets or audio/visual content.

The distributor 108 may use the same or different chunk size for any of the communication channels. Furthermore, the distributor 108 may change the chunk size at any time, in response to an analysis of any desired chunk size criteria. One example of a chunk size criteria is desired channel change speed at the destination 104. As the number of packets in a chunk increases, the destination 104 may need to drop more packets before reaching the next chunk boundary, finding the matching MPs, and being able to synchronize to the received communication channels. The chunk size may also depend on compressed video rate or frame size, as well as target, average, or worst case recovery time for recovering from transmission errors or other transmission issues.

In the example in FIG. 6, the statistical multiplexer 106 receives program packets from input sources 1 . . . ‘n’. The program packets may be MPEG2 TS packets, or any other type of packet. The statistical multiplexer 106 creates a STS 110 from the program packets, and the STS 110 therefore has a particular sequence of packets multiplexed into the STS 110 from the various input sources according to the statistical properties of the program streams.

For the purposes of illustration, FIG. 6 shows the first six chunks that the distributor 108 has decided to send over the communication channels. In particular, the first three chunks are two-packet chunks 602, 604, and 606. The next two chunks are one-packet chunks 608 and 610. The next chunk is a two-packet chunk 612.

The distributor 108 generates MPs that precede the chunks. Alternatives are possible, however, and some are described below with respect to FIGS. 15 and 16. The distributor 108 may communicate the MPs and the chunks (e.g., in a round-robin manner) across the communication channels. In the example of FIG. 6, the distributor 108 sends a MP (e.g., MP-0, MP-1, and MP-2) to each communication channel, followed by a two-packet chunk behind MP-0, MP-1, and MP-2, in round-robin sequence: channel 1, channel 2, channel m, and then returning to channel 1. The distributor 108 may start the sequence with any particular communication channel.

As is shown in FIG. 6, the communication channels receive MPs and chunks in round-robin manner starting with channel 1 as follows:

Channel 1: MP-0; Channel 2: MP-1; Channel 3: MP-2

Channel 1: chunk 602; Channel 2: chunk 604; Channel 3: chunk 606

Channel 1: MP-4; Channel 2: MP-5; Channel 3: MP-6

Channel 1: chunk 608; Channel 2: chunk 610; Channel 3: chunk 612

Because chunk boundaries are marked with MPs, the distributor 108 may insert compensation packets (e.g., NULL packets) without affecting the channel bonding. In other words, each communication channel may have its own unique payload rate. Furthermore, MPEG2 TS corruption during transmission does not affect other packets.

Each MP may include a channel number and a group number, as described above. The channel and group numbers may take a wide variety of forms, and in general provide sequence indicators. Take the example where the chunk size is 100 packets and there are three communication channels A, B, and C, with the distributor 108 proceeding in this order: C, B, A, C, B, A, . . . . The first set of MPs that come before the first 100 packet chunks may each specify group number zero. Within group zero, the first MP on communication channel C has a channel number of zero, the second MP on communication channel B has a channel number of one, and the third MP on the communication channel A has a channel number of two. For the next group of chunks of 100 packets, the MP group number for the next three MPs may increment to one, and the channel numbers run from zero to two again.

At the destination 104, the demodulators 116 receive the MPs and chunks from each communication channel. Again, individual FIFOs 204 may be provided to help compensate for jitter and skew.

The collator 118 receives the MPs, and synchronizes on the received data streams when the collator 118 finds MPs of the same group number and in sequence across the communication channels that are part of the bonded channel group 112. Once the collator 118 has synchronized, it obtains each chunk following the MPs in order of group number and channel number. In this manner, the collator 118 constructs the DTS 120 that corresponds to the STS 110. As described above, the TIP 122 executes PID filtering on the MPEG2 TS packets to recover any desired program j, and may discard the other packets.

FIG. 7 shows an example of logic 700 for content delivery using channel bonding, that may be implemented in hardware or software in the example architecture 600 described above. Input sources receive program data (702). The input sources provide the program data to the statistical multiplexer 106 (704), which multiplexes the program data to generate the source transport stream (STS) 110 (706). The distributor 108 receives the STS 110 (708).

The distributor 108 also reads bonding configuration parameters (710). The bonding configuration parameters may, for example, specify that the distributor 108 should take the round-robin distribution approach, and may specify round-robin distribution parameters. Examples of such parameters include the round-robin distribution chunk size, e.g., ‘r’ packets at a time per communication channel (e.g., r=100), chunk size per communication channel, or chunk size variation in time, or variation depending on chunk size factors that the source 102 may monitor and adapt to over time, in what situations the distributor 108 should execute the round-robin technique, or any other round-robin parameter. As noted above, the bonding configuration parameters may also specify the number of communication channels in the bonding channel group 112, the communication channels that may be included in the bonding channel group 112, the type of communication channels that may be included in the bonding channel group 112, the program sources eligible for bonding, when and for how long communication channels and program sources are available for channel bonding, and any other parameters that may influence how the distributor 108 pushes program data across the communication channels in the bonded channel group 112.

In this option, the distributor generates MPs (712) for the chunks of program packets that the distributor sends through the individual communication channels in the bonded channel group 112. Thus, for example, when the bonding configuration parameters indicate a chunk size of 100 packets, the distributor generates a MP for each 100 program packets communicated down the communication channel. As was explained above, a MP may include synchronization data, such as a group number and channel number. As another example, the MP may include timing data such as a timestamp, time code, or other timing reference measurement.

The distributor 108 sends the MPs and the program data to the communication channels in the bonded channel group 112 (714). The distributor 108 may send the MPs and program data in a round-robin manner by communication units of program packets (e.g., by chunks of program packets). The source 102 thereby communicates program data to the destination 104 across the multiple communication channels in the bonded channel group 112 (716).

More particularly, the distributor 108 may send the program packets to the communication channels in round-robin manner by chunk. In other words, the distributor 108 may take chunks of program packets from the STS 110 and send them to the next communication channel in the bonded channel group 112 in a predetermined round-robin sequence (e.g., as specified in the bonding configuration parameters). As such, an MP is distributed to a communication channel, and is followed by a chunk of program packets tagged by the MP in terms of group number and channel number. The program packets include PID information that identifies the program to which each packet belongs. The MPs thereby effectively flag for the destination 104 the program packets that follow the MPs. After each chunk of program packets, the distributor 108 provides another group of MPs that are then distributed across the communication channels, and the cycle repeats. The chunk size may vary in time and by communication channel. Furthermore, the source 102 may send configuration communications to the destination 104 to advise the destination 104 of the bonding configuration and changes to the bonding configuration, including chunk size.

At the destination 104, the demodulators 116 receive the program data over the communication channels (718). The demodulators 116 provide the recovered program data to buffers (e.g., the FIFOs 304) to help address jitter/skew (720) on the communication channels. The buffered data is provided to the collator 118, which may pull packets from the buffers to synchronize on MPs. The collator 118 analyzes group information, sequence information, PIDs, and any other desired information obtained from the MPs and program packets to synchronize on MPs. The synchronization may include finding sequential MPs of the same group number across each communication channel in the bonded channel group 112.

The collator 118 then creates a destination transport stream (DTS) 120 from the recovered program data (722) by adding packets to the DTS 120 in a round-robin manner across the communication channels in the bonded channel group 112. In particular, the collator 118 adds packets to the DTS 120 by chunk of program packets in a round-robin manner across the communication channels in the bonded channel group 112. Thus, the DTS 120 may convey the program packets to the TIP 122 in the same sequence as they were present in the STS 110, for example.

The collator 118 provides the DTS 120 to the TIP 122 (724), which reads channel selection parameters (726). The channel selection parameters may specify, for example, which program is desired, and may be obtained from viewer input, from automated selection programs or processes (e.g., in a smart phone content recording application), or in other ways. Accordingly, the TIP 122 filters the DTS 120 to recover the program packets that match the channel selection parameters (e.g., by PID filtering) (728). The TIP 122 thereby generates a content output that includes an output packet stream for the selected program. The TIP 122 delivers the generated content to any desired device 124 that consumes the content, such as televisions, smart phones, personal computers, or any other device.

Turning briefly to FIG. 15, that figure shows an example variation architecture 1500 of the content delivery architecture 600 in FIG. 6. In one variation, the distributor may instead issue MP generation signals (e.g., the MP generation signals 1502, 1504, 1506) to the modulators 130. The MP generation signal 1502 may be a command message, signal line, or other input that causes the receiving modulator to generate a MP for insertion into the packet stream, e.g., at chunk boundaries. The MP may include any desired synchronization information, including time stamps, time codes, group numbers, channel numbers, and the like. The modulator may generate the synchronization information, or the distributor 108 may provide the synchronization information to the modulator along with the MP generation signal.

In another variation, both the distributor 108 generates MPs and the modulators 130 generate MPs. For example, the distributor 108 may generate the MPs for the modulator for CH2 and send MP generation signals to the modulators for the other channels. Another alternative is for the distributor 108 to generate MPs for some modulators some of the time, and to send MP generation signals to those modulators at other times. Whether or not the distributor 108 generates the MPs may depend on MP capability information available to the distributor 108. For example, the bonding configuration parameters 710 may specify which modulators are capable of generating MPs, when, and under what conditions. Then, the distributor 108 may send the MP generation signal to those modulators at the corresponding times or under the corresponding conditions. Further, the modulator may communicate with the distributor 108 to specify MP generation capabilities, and the conditions on those capabilities, such as when and under what conditions the modulator can generate MPs, and also what information the modulator needs from the distributor 108 to generate the MPs.

Turning briefly to FIG. 16, that figure shows content delivery logic 1600 for the architectures described above. FIG. 16 shows again that, in the architectures described above (e.g., 1500 and 600), the distributor 108 may generate MPs, the modulators 130 may generate MPs, or both may generate MPs. For example, FIG. 16 shows that for the modulator for CH1, the distributor 108 generates the MPs (1602), e.g., at chunk boundaries. The distributor 108 also generates the MPs for the modulator for CHm (1606). However, for the modulator for CH2, the distributor 108 sends an MP generation signal and any desired synchronization information (1604) to the modulator for CH2. Accordingly, the modulator for CH2 generates its own MPs for the chunks it receives from the distributor 108. Note also that any modulator may communicate with the distributor 108 to specify MP generation capabilities, and the conditions on those capabilities, including when and under what conditions the modulator can generate MPs, as well as what information the modulator needs from the distributor 108 to generate the MPs (1608).

Turning now to FIG. 8, the figure shows an example implementation of a distributor 800. The distributor 108 includes an STS input interface 802, system logic 804, and a user interface 806. In addition, the distributor 800 includes modulator output interfaces, such as those labeled 808, 810, and 812. The STS input interface 802 may be a high bandwidth (e.g., optical fiber) input interface, for example. The modulator output interfaces 808-812 feed data to the modulators that drive data over the communication channels. The modulator output interfaces 808-812 may be serial or parallel bus interfaces, as examples.

The system logic 804 implements in hardware, software, or both, any of the logic described in connection with the operation of the distributor 108 (e.g., with respect to FIGS. 1-7 and 10). As one example, the system logic 804 may include one or more processors 814 and program and data memories 816. The program and data memories 816 hold, for example, packet distribution instructions 818 and the bonding configuration parameters 820.

The processors 814 execute the packet distribution instructions 818, and the bonding configuration parameters 820 inform the processor as to the type of channel bonding the processors 814 will perform. As a result, the processors 814 may implement the round-robin packet by packet distribution or round-robin chunk by chunk distribution described above, including MP generation, or any other channel bonding distribution pattern. The distributor 800 may accept input from the user interface 806 to change, view, add, or delete any of the bonding configuration parameters 820 or any channel bonding status information.

FIG. 9 shows an example implementation of a collator 900. The distributor 108 includes a DTS output interface 902, system logic 904, and a user interface 906. In addition, the collator 900 includes demodulator input interfaces, such as those labeled 908, 910, and 912. The DTS output interface 902 may be a high bandwidth (e.g., optical fiber) output interface to the TIP 122, for example. The demodulator output interfaces 908-912 feed data to the collator system logic which will create the DTS 120 from the data received from the demodulator input interfaces 908-912. The demodulator input interfaces 908-912 may be serial or parallel bus interfaces, as examples.

The system logic 904 implements in hardware, software, or both, any of the logic described in connection with the operation of the collator 118 (e.g., with respect to FIGS. 1-7 and 10). As one example, the system logic 904 may include one or more processors 914 and program and data memories 916. The program and data memories 916 hold, for example, packet recovery instructions 918 and the bonding configuration parameters 920.

The processors 914 execute the packet recovery instructions 918, and the bonding configuration parameters 920 inform the processor as to the type of channel bonding the processors 914 will handle. As a result, the processors 914 may implement the round-robin packet by packet reception or round-robin chunk by chunk reception described above, including MP synchronization, or any other channel bonding distribution recovery logic. The collator 900 may accept input from the user interface 906 to change, view, add, or delete any of the bonding configuration parameters 920, to specify which channels are eligible for channel bonding, or to set, view, or change any other channel bonding status information.

The architectures described above may also include network nodes between the source 102 and the destination 104. The network nodes may be type of packet switch, router, hub, or other data traffic handling logic. The network nodes may be aware of the communication channels that they are connected to, both on the inbound side, and on the outbound side. Accordingly, a network node may receive any particular set of communication channels in a channel bonding group, but need not have a matching set of communication channels in the outbound direction. In that case, the network node may filter the received communication channel traffic, to drop packets for which the network node does not have a corresponding outbound communication channel, while passing on the remaining traffic flow over the outbound communication channels to which it does have a connection.

In concert with the above, the channel bonding may happen in a broadcast, multicast, or even a unicast environment. In the broadcast environment, the source 102 may send the program packets and MPs to every endpoint attached to the communication channels, such as in a wide distribution home cable service. In a multicast environment, however, the source 102 may deliver the program packets and MPs to a specific group of endpoints connected to the communication channels. In this regard, the source 102 may include addressing information, such as Internet Protocol (IP) addresses or Ethernet addresses, in the packets to specifically identify the intended recipients. In the unicast environment, the source 102 may use addressing information to send the program packets and the MPs across the bonded channel group 112 to a single destination.

A third option is to add, at the source 102, channel bonding data fields to the program packets. The channel bonding data fields may be added to the packet header, payload, or both. The channel bonding data fields may identify for the destination 104 how to order received packets to create the DTS 120. In that regard, the channel bonding data fields may include PID information, sequence information, channel number information, group number information, or other data that the collator 118 may analyze to determine packet output order in the DTS 120.

In some implementations, a communication head-end may define the program packets that each source will employ, and therefore has the flexibility to create channel bonding fields in the program packets. In other implementations, the source 102 inserts channel bonding data into existing packet definitions (possibly using part of a conventional data field for this new purpose). For example, in some implementations, each program is formed from multiple MPEG2 PIDs, with each MPEG2 TS packet being 188 bytes in size. When packets from the same program will be routed across different communication channels, the source 102 may use header or payload fields in the MPEG2 TS packets to carry channel bonding fields (e.g., PID and sequence number) in the MPEG2 TS packets.

As one example, the source 102 may add, as channel bonding data, a program ID (PID) and sequence number to program packets. The PID may be a 4-bit field that identifies one of 16 different programs. The sequence number may be a 12-bit field that identifies one of 4096 sequence values. In this implementation, the source 102 need not send MPs. Instead, the channel bonding information (e.g., PID and sequence number) inserted into the program packets provides the destination 104 with the information it uses to construct the DTS 120. More specially, the collator 118 identifies the PIDs and the packets with sequential sequence numbers for each PID, and creates the DTS 120 with the correct packet sequence.

Furthermore, the source 102 may also insert the channel bonding data into lower layer packets. For example, instead of (or in addition to for redundancy), sending MPs defined at or above the transport layer, the source 102 may instead insert the channel bonding data into frames defined below the transport layer, such as data-link layer frames or physical layer frames. As an example, the data-link layer frames may be Low Density Parity Check (LDPC) frames, and the physical layer frames may be Forward Error Correcting (FEC) frames.

Because such frames are defined at the data-link layer, higher layers may have no knowledge of these frames or their formats, and generally do not process such frames. Nevertheless, the higher level layers, including the transport layer, may provide bonding information to the data-link layer that facilitates data-link layer handling of the channel bonding data. Examples of such bonding information includes the amount and type of channel bonding data desired, including the definitions, sizes, and sequence numbering of channel number and sequence number fields, desired chunk size, number, identification and type of communication channels to bond, or any other channel bonding information.

In more detail, in some communication architectures, the data-link layer packets have spare, reserved, or otherwise ancillary bits. Instead of having the ancillary bit fields remain unused, the system 102 may insert the channel bonding data in those ancillary bit fields. In other implementations, the data-link layer may define its own particular packet format that includes bit fields specifically allocated for channel bonding data.

FIG. 10 shows an example of a content delivery architecture 1000 that performs channel bonding below the transport layer, e.g., at the data-link layer or physical layer. FIG. 10 extends the example of FIG. 6 for the purposes of discussion, but channel bonding at lower layers may occur in any content delivery architecture. In FIG. 10, a protocol stack at the distributor 108 includes multiple layers, including a Physical (PHY) layer 1002, a data-link layer 1004, a transport layer 1006, and any other layers desired 1008. The protocol stack may adhere to the Open Systems Interconnection (OSI) model, as one example, and the data-link layer and physical layer structures that may carry channel bonding information may include, as examples, Forward Error Correcting (FEC) frames, PHY frames, MAC frames, Low Density Parity Check (LDPC) frames, or IP Datagram frames. However any other protocol stack and structure types may instead be in place to handle channel bonding at a level below the level at which the program packets.

The STS 110 provides the program packets to the distributor 108. The protocol stack handles the program packets. In particular, the data-link layer 1004 constructs low level frames that encapsulate program packets and channel bonding data, and that are sent across the communication channels in the bonded channel group 112. One example of the low level frames is the data-link frame 1010. In this example, the data-link frame 1010 includes channel bonding (CB) data, data-link frame (DLF) data, and program packets (in particular, the first chunk 602). The DLF data may include the information fields in an already defined data-link layer packet format. The CB data may include channel number and group number information, or any other information that a MP might otherwise carry.

Higher level layers may (e.g., the transport layer 1006 or other layers 1008), as noted above, provide guidance to the data-link layer 1004 regarding what bonding information to include in the data-link layer frames. However, this is not required. The data-link layer may do its own analysis and makes its own decisions concerning what channel bonding data to add into the data-link layer frames. In that regard, the data-link layer may read the channel bonding configuration parameters. The data-link layer may also exchange the configuration communications 126 with the destination 104, including configuration communications 126 with the data-link layer, transport layer, or other layers at the destination 104.

At the destination 104, a protocol stack 1012 processes the data received from the demodulators 116. In particular, the protocol stack 1012 may include a data-link layer 1014. The data-link layer 1014 receives the data-link layer frames (e.g., the frame 1010) to extract the program packets and channel bonding data. The collator 118 may then process the channel bonding data as described above to synchronize the communication channels in the bonded channel group 112 and build the DTS 120.

FIG. 11 shows an example of channel bonding using data-link layer frames 1100. In FIG. 11, a data stream 1102 represents, for example, source data prior to packetization. The data stream 1102 may be as examples, data generated by a video camera, microphone, or bytes in a file on a disk drive. A content provider generates a packetized stream 1104, for example in the form of MPEG2 TS packets 1106. The packets 1106 may take many different forms, and in the example shown in FIG. 11, the packets 1106 include Cyclic Redundancy Check (CRC) data 1108 (e.g., in a header), and a payload 1110.

FIG. 11 also shows the data-link layer frames 1112. In this example, the data-link layer frames 1112 include a header 1114 and a payload 1116. The header 1114 may include fields in which, although they are pre-defined for other purposes, the data-link layer 1004 inserts channel bonding data, such as channel number and group number. FIG. 11 shows an example in which the data-link layer frame 1112 includes an MATYPE field 1118 (e.g., 2 bytes), a UPL field 1120 (e.g., 2 bytes), a DFL field 1122 (e.g., 2 bytes), a SYNC field 1124 (e.g., 1 byte), a SYNCD field 1126 (e.g., 2 bytes), and a CRC field 1128 (e.g., 1 byte). This particular frame format is further described in the DVB S2 coding and modulation standard, In particular, the data-link layer 1104 may insert the channel bonding information into the MATYPE field 1118.

The framing of the data-link layer 112 is such that program packets are generally encapsulated into the payload 1116 of the data-link frame 1112, while the channel bonding information is added to the header 1204. However, note the packetized stream 1104 does not necessarily line up with the data-link layer frames 1112. This is shown by the dashed lines in FIG. 11, with the data-link layer frame 1112 breaking across program packets. The lack of alignment may be due to timing and packet size mismatches between various layers in the protocol stack, and because the data stream 1102 does not necessarily adhere to any fixed timing parameters or data formats.

In some implementations, the architectures may facilitate alignment by inserting packets (e.g., NULL packets) of any desired length, padding program packets (e.g., with NULL data), truncating program packets (or otherwise dropping program packet data), dropping program packets altogether, or in other ways. The data-link layer 1004 may execute the alignment in order to fit an integer number of program packets into a data-link layer frame. In some implementations, the data-link layer 1004 may communicate with other layers in the protocol stack, or other logic in the source 102, to provide guidance on timing, alignment, chunk sizes, or other bonding parameters that may facilitate alignment and channel bonding at the data-link layer.

FIG. 12 shows an example of channel bonding using data-link layer frames 1200. As with FIG. 11, in FIG. 12 a data stream 1102 represents, for example, source data prior to packetization, and the packetized data stream 1104 arises from the data stream 1102. The data-link layer frame 1202 includes a header 1204 and a payload 1206. However, in FIG. 12, data-link layer frame 1202 has been designed to include fields specifically for channel bonding information. In the example in FIG. 12, the header 1204 includes the channel bonding field 1 1208 and the channel bonding field 2 1210. Other header fields 1212 carry other header information. Any number and length of channel bonding fields may be present in either headers or payload fields in the data-link layer frames to hold any desired channel bonding information.

FIG. 13 shows an example of logic 1300 that a data-link layer in the source 102 may implement for channel bonding at the data-link layer. The data-link layer may provide feedback to higher layers (1302). The feedback may inform the higher level layers about alignment, timing, or other considerations that affect how program packets break across or fit into data-link layer packets.

The data-link layer receives program packets from the higher level layers (1304). If the data-link layer will force alignment, then it may pad program packets, insert alignment packets, or even drop packets or parts of packets, so that the program packets fit within the data-link layer frame (1306) in a way that corresponds to the selected channel bonding configuration, including, for example, the chunk size. The data-link layer inserts channel bonding information into data-link layer frames (1308). In some implementations, the protocol stack at the source 102 does not generate separate marker packets for the channel bonding information. That is, the low level communication frames (e.g., the data-link layer frames) carry the channel bonding information in specific fields defined in the communication frames, so that no separate encapsulation of the channel bonding information (into marker packets, for example), is needed. Expressed yet another way, the data-link layer frames may have one less layer of encapsulation, e.g., encapsulating the channel bonding information directly into the low level communication frame, rather than multiple levels of encapsulation, e.g., encapsulating the channel bonding information first into a MP defined, e.g., at the same protocol level as a program packet, and then the MP into the communication frame.

The data-link layer also inserts program packets or chunks of packets into data-link layer frames. For example, the program packets may exist in the payload field of the data-link layer frames. The marker information may specify which packets are present in the data-link layer frame with the marker information (1310). The data-link layer then transmits the data-link layer frames over a communication channel that is part of a bonded channel group 112.

FIG. 14 shows an example of logic 1400 that a data-link layer in the source 102 may implement for channel debonding at the data-link layer. The data-link layer receives data-link layer frames (1402). The data-link layer extracts the program packets and the channel bonding information from the data-link layer frames (1404). Any padding data in the program frames, or padding packets may be discarded (1406).

The destination 104 analyzes the channel bonding information to synchronize across multiple communication channels, as described above (1408). Accordingly, for example, the destination may align to channel bonding sequence information across multiple communication channels. Once synchronized, the destination 104 may construct the DTS 120, for example by round-robin adding chunks to the DTS 120 from the data-link layer frames, informed by the channel bonding information in the data-link layer frames (1410).

One example format for a MP is the following:

CBM_PID: ChannelBondingMarker PID, which may be a reserved PID value for a marker packet. In some implementations, MPs may include adaptation layer information and follow the MPEG2 TS packet structure, although some or all of the content of the packet will be specific to MP data instead of, e.g., program data. The bytes in the MP may be assigned as follows (as just one example):

Byte #1: 0x47 (MPEG2 TS pre-defined sync byte)

Byte #2/3: CBM_PID+TEI=0, PUSI=0, priority=1

Byte #4: SC='b00, AFC='b11 (no payload), CC=0x0

Byte #5: Adaptation_length='d183

Byte #6: Flags=0x02, e.g., only private data is present

Byte #7: Private data_length='d181

Byte #8: Number of channels in Channel Bonding group

Byte #9/10: CBM_Sequence_Number (CBM_SN)

Byte #11/12/13/14: CBM_SIZE

This generic MPEG2 TS packet syntax is further explained in ISO/IEC 13818-1, section 2.4.3.2, “Transport Stream packet layer”.

In some implementations, channels of different network types may also be bonded together. As such, devices with multiple communication interfaces may utilize additional bandwidth that otherwise would be idle. Further, the device may dynamically adapt to the type of data and available communication interfaces to maximize the quality and reliability of the data being transmitted.

Several channel bonding processing options have been discussed herein. In the first option, the distributor 108 adds marker packets on a per-channel basis, for example in a round-robin manner. In the second option, the distributor 108 generates and adds markers on a per-chunk basis, for example in a round-robin manner at chunk boundaries. In the third option, when packets from the same program will be routed to multiple communication channels, each packet receives a program ID and a sequence ID, and no marker packets are needed. In the fourth option, spare bits in network frames defined below the network layer, e.g., at the data-link layer, carry channel bonding information to the source 104. Further other options may exist. However, any of the architectures or features of these techniques may be used together in conjunction with the discussed implementations for bonding channels with different network types.

FIG. 17 illustrates multiple different communication network types that may be available on home networks. For example, certain devices may have one or more of the network types illustrated while other devices may have a different combination of communication network types. Further, each communication network type may offer a different tradeoff with regard to performance, availability, and cost. Some strategies are available for switching communication from one network to another network such as IEEE1905, denoted by reference numeral 1710.

In one example, a device may have a PLC interface 1714 and a WiFi interface 1712. Accordingly, a device may establish communication with another device on the network through either the PLC interface 1714 or separately the WiFi interface 1712 depending on which network is available at the time. Such switching capabilities are denoted by reference numeral 1716. However, a number of different network types may also be used in a channel bonding scenario. Through channel bonding, communication may be established through multiple communication network types at the same time. Packets and/or communication units (e.g. chunks) may be distributed across multiple communication networks for the same information stream. For example, a coax communication device may also be used interchangeably with a PLC interface 1714 and the WiFi interface 1712, as denoted by reference numeral 1722.

A schematic of a system 1800 for channel bonding across multiple network types is provided in FIG. 18. A first device 1810 may transmit information to a second device 1820 through two bonded networks. The first device 1810 may be configured to communicate through a first network such as a MoCA network 1812 and a second network such as IEEE 1901 network 1814. In this implementation, the first network 1812 may be channel bonded with the second network 1814, such that each packet or communication unit of the data stream being communicated between the first device 1810 and the second device 1820 are distributed between the first channel 1812 and the second channel 1814. The first device 1810 may provide different communication unit sizes to each network type, for example, based on network bandwidth. Further, the first device may dynamically change the bit rate or transcoder rate for each communication channel based on the number and type of channels available to communicate with the second device 1820.

The first device 1810 may allocate different channel bonding buffer sizes for each network type. Further, the system may determine the network buffer size based on attributes of the network type. The attributes may include bit rate, availability, signal strength, power consumption, or reliability. In addition, the first device 1810 may communicate with the second device 1820 to determine network types available to the second device 1820 for communication, as well as, preferences stored on the second device 1810 for receiving communication from the first device 1810.

In some implementations, the first device 1810 may determine that certain content is high priority content. The first device 1810 may identify high priority content, for example, based on data stored in the marker packet. In this scenario, the first device 1810 may choose to send a communication unit having a high priority content through a particular network type. For example, the first device 1810 may send high priority data through a specific network type that has a certain level of reliability, or at least the highest reliability of the available communication channels. Alternatively, the first device 1810 may be configured to send high priority communication units through multiple channels redundantly. As such, the communication unit may be sent through multiple different network types redundantly. High priority data may include information such as base layer packets or I-frame packets of video streams.

FIG. 19 illustrates one implementation of the control scheme for a channel bonding system. The system 1900 may be configured to communicate through a plurality of networks 1926. The networks may include WiFi, IEEE 1901, MoCA, Ethernet, or other similar networks including, but not limited to, all those discussed herein. Further, in some implementations, this concept may be extended to additional network types including 3G, 4G, and LTE or any other wired or wireless network. Each network is controlled by the corresponding physical layer 1924. Each physical layer is connected to a media access control layer 1922 (MAC). Often the MAC layer is software that controls the physical layer. The MAC layer often provides a common interface 1920 that is similar to other MAC layers. The interface 920 allows for increased interchangeability between communications sent to each network type.

In the implementation shown, the MAC interfaces may be connected to IEEE 1905.1 MAC abstraction layer 1914 for controlling home networks. As such, the MAC abstraction layer 1914 may communicate and receive data through a channel bonding application layer 1910. The channel bonding application layer 1910 may communication with the MAC abstraction layer 1914 through a channel bonding adaptation layer interface 1912.

The channel bonding adaptation layer 1910 may determine communication unit and/or packet distribution and insert marker packets. Examples of techniques for distributing packets among communication channels are described throughout this application. Further, the channel bonding adaptation layer 1910 may determine packet distribution based on channel conditions, such as the bit rate of each channel. This information may be received from the MAC abstraction layer 1914 through the channel bonding application layer interface 1912. The channel bonding adaptation layer 1910 may also configure the channel bonding group and adaptively send packets to different channels based on changing network conditions or characteristics of the data being passed.

FIG. 20 is a flow chart illustrating the method 2000 for channel bonding across different network types. The channel boding group may be configured by the channel bonding application layer (2010). The bit rate in the channel bonding group may be obtained from the MAC abstraction layer (2012). Bonding buffers may then be allocated for each channel (2014). The buffers from each channel may be allocated based on the bit rate for that channel. The system may determine bonding characteristics (2016) such as the packet data types, the condition of each channel, and the buffer fullness for each channel. The system may then tag and assign packets to each channel based on the determined characteristics (2018). The method may then continue (2020) such that bonding characteristics are continually monitored and packets are assigned adaptively based on any change in characteristics.

FIG. 21 is a schematic of a home network configured to use adaptive channel bonding. The home network 2100 may include a gateway 2110 which may include a router or modem configured to receive data from outside the home network. The gateway 2110 may receive data from, for example, coax, T1, or other network configured to receive information from external sources (e.g. a headend). The home network 2100 may also include a number of other devices including a first set top box (STB) 2112, a PC 2118, a second set top box 2114, a DVR 2116 and a hard drive 2120. The first set top box 2112, second set top box 2114, the DVR 2116, and the PC 2118 may all be connected to the gateway 2110 and each other through multiple network interfaces such as MoCA 2122, WiFi 2124, and power line 2126 to act as a single logical channel. Although this example will be described with regard to those three interfaces, multiple additional interfaces may also be used and bonded together in various configurations.

In this manner, the gateway 2110 may bond together in various configurations the MoCA network 2122, the WiFi network 2124, and the powerline network 2126. The gateway 2110 can communicate with each of the other devices through the bonded channel group. Accordingly, the information coming through the gateway 2110 may be assigned to communication units and distributed to one or more of the networks 2122, 2124, 2126, such that the data may be received by the appropriate device on the network. The gateway 2110 may adaptively select the communication channel to use based on amount of data and/or the priority of the data to be transmitted, as well as, characteristics of the network for each communication channel. For example, the gateway 2110 may consider network characteristics including network availability, network reliability, bit rate, signal strength and power requirements.

In a similar manner, devices within the network can also communicate in this fashion. For example, the communication between the first set top box 2112 and the DVR 2116 may also be facilitated in a channel bonded configuration. For example, the set top box 2112 may communicate with the DVR 2116 by distributing communication units across both the MoCA and WiFi networks adaptively, according to various network characteristics and the type of data being transmitted. In addition, the DVR 2116 may communicate back with the set top box 2112 via a different channel bonded configuration using either of the same or different networks available to the DVR 2116. In some implementations, the set top box 2112 may establish communication with the DVR 2116 and receive information from the DVR 2116 indicating that only MoCA and WiFi networks are available for communication to the DVR 2116. In this case, the set top box 2112 may adaptively select between the two available communication channels for distributing packets and/or communication units adaptively to the DVR 2116. Although it is understood, that while the above description illustrates communication between the first set top box 2112 and the DVR 2116, the same communication may be established between any of the devices within the home network. As such, each device may include software and/or hardware for distributing communication units as described with regard to FIG. 22.

In some implementations, the gateway 2110 may attempt to communicate with a device, such as the hard drive 2120. However, the communication may only be available through another device on the network, such as a PC 2118. However, in some implementations not all communication networks are transferred through the PC 2118 to the hard drive 2120. Accordingly, while the channel bonding information is distributed and transmitted across the three bonded communication channels to the PC 2118, the PC 2118 may redistribute the communication units/packets across the fewer number of networks to the device 2120. Alternatively, the gateway 2110 may be in communication with the PC 2118 to determine which networks are available to the hard drive 2120. As such, the gateway 2110 may select to provide communication units/packets that will be delivered to the hard drive across certain communication channels that will be passed through the PC 2118 to the hard drive 2120.

FIG. 22 is a schematic illustration of a device 2210 which may correspond to any of the devices in the previous FIG. 21, such as the gateway 2110, the first set top box 2112, the PC 2118, the hard drive 2120, the second set top box 214, or the DVR 2116. Accordingly, each device 2110 may include a processor 2212 configured to receive a stream of data for communication. The stream of data may be received by distributor 2214. The distributor 2214 may analyze the data stream to determine data characteristics. In addition, the distributor 2214 may also analyze delivery mechanism (e.g. modulator and/or buffer) for each network. For example, the distributor 2214 may communication with a MoCA delivery mechanism 2216, a WiFi delivery mechanism 2218, and a powerline delivery mechanism 2220.to understand the characteristics for each network. Based on the data characteristics and the network characteristics, the distributor 2214 may assign the data to communication units and/or insert marker packets that are provided adaptively to one or more of the network communication mechanisms (2216, 2218, 2220).

In certain video applications, a base layer may be determined to have a higher priority than other enhanced layers. As such, the base layer may be determined to be communicated through a particular network having a higher reliability such as MoCA, while enhanced layers may be distributed to the other layers based on availability and other characteristics such as buffer fullness.

In particular implementations I-frames may be provided over particular network having higher reliability, such as MoCA, whereas B-frames and P-frames may be distributed via other channels based on the availability of those channels (e.g. based on bit rate as determined by buffer fullness). In some other implementations, the base layers or I-frames may be provided across multiple networks if reliability characteristics of the available networks fall below a predefined level.

The methods, devices, and logic described above may be implemented in many different ways in many different combinations of hardware, software or both hardware and software. For example, all or parts of the system may include circuitry in a controller, a microprocessor, or an application specific integrated circuit (ASIC), or may be implemented with discrete logic or components, or a combination of other types of analog or digital circuitry, combined on a single integrated circuit or distributed among multiple integrated circuits. All or part of the logic described above may be implemented as instructions for execution by a processor, controller, or other processing device and may be stored in a tangible or non-transitory machine-readable or computer-readable medium such as flash memory, random access memory (RAM) or read only memory (ROM), erasable programmable read only memory (EPROM) or other machine-readable medium such as a compact disc read only memory (CDROM), or magnetic or optical disk. Thus, a product, such as a computer program product, may include a storage medium and computer readable instructions stored on the medium, which when executed in an endpoint, computer system, or other device, cause the device to perform operations according to any of the description above.

The processing capability of the architectures may be distributed among multiple system components, such as among multiple processors and memories, optionally including multiple distributed processing systems. Parameters, databases, and other data structures may be separately stored and managed, may be incorporated into a single memory or database, may be logically and physically organized in many different ways, and may implemented in many ways, including data structures such as linked lists, hash tables, or implicit storage mechanisms. Programs may be parts (e.g., subroutines) of a single program, separate programs, distributed across several memories and processors, or implemented in many different ways, such as in a library, such as a shared library (e.g., a dynamic link library (DLL)). The DLL, for example, may store code that performs any of the processing described above. While various embodiments of the invention have been described, it will be apparent to those of ordinary skill in the art that many more embodiments and implementations are possible within the scope of the invention. Accordingly, the invention is not to be restricted except in light of the attached claims and their equivalents. 

What is claimed is:
 1. A system comprising: an input interface; output interfaces to individual communication channels, wherein the individual communication channels comprise different network types; and processor in communication with the input interface and the output interfaces, the processor configured to: determine which of the communications channels to employ together as a bonded channel group; obtain source data from the input interface; and distribute the source data across the communication channels in the bonded channel group to the different network types in response to a data type of the source data.
 2. The system according to claim 1, wherein the processor is configured to determine which of the different network types are available.
 3. The system according to claim 2, wherein the processor is configured to change a bit rate based on the different network types that are available.
 4. The system according to claim 2, wherein the processor is configured to change transcoder parameters based on the different network types that are available.
 5. The system according to claim 1, wherein the processor is configured to assign packets of the data source into chunks, the processor being configured to select a chunk size based on the network type.
 6. The system according to claim 1, wherein the processor is configured to allocate a channel bonding buffer for each communication channel, the processor being configured to select a size of the channel bonding buffer based on the network type of the communication channel.
 7. The system according to claim 1, wherein the output interfaces connect to an in-home network and the network types include at least two of MoCA, WiFi, powerline, and Ethernet.
 8. The system according to claim 1, wherein the processor is a component of a gateway.
 9. The system according to claim 8, wherein the gateway is configured to communicate with a set top box to receive a communication channel preference from the set top box.
 10. The system according to claim 1, wherein the processor is a component of a set top box.
 11. The system of claim 1, wherein the processor is configured to distribute the data in a round-robin manner across the bonded channel group.
 12. A method comprising: obtaining a packet stream; dividing the packet stream into communication units; identifying a bonded channel group of communication channels among a set of available communication channels, wherein a first channel of the bonded channel group has a first network type and a second channel of the bonded channel group has as second network type different from the first network type; and distributing the communication units across the bonded channel group.
 13. The method of claim 12, further comprising obtaining a bit rate for each communication channel in the channel bonding group.
 14. The method of claim 12, further comprising allocating packets to communication channels based on a data type contained in the communication unit.
 15. The method of claim 12, further comprising allocating packets to communication channels based on a channel condition of a communication channel of the bonded channel group.
 16. The method of claim 12, further comprising allocating a buffer for each channel in the channel bonding group, allocating packets to communication channels based on buffer fullness.
 17. The method of claim 12, further comprising distributing marker packets across the channel bonding group in advance of the communication units.
 18. A method comprising: obtaining a packet stream; dividing the packet stream into communication units; identifying a bonded channel group of communication channels among a set of available communication channels, wherein a first channel of the bonded channel group has a first network type and a second channel of the bonded channel group has as second network type different from the first network type; distributing a first communication unit to the first channel in response to the first communication unit having a first data type; and distributing a second communication unit to the second channel in response to the second communication unit having a second data type.
 19. The method according to claim 18, wherein the first communication unit is distributed to the first channel in response to the first communication unit comprising I-frame data.
 20. The method according to claim 18, wherein the first communication unit is distributed to the first channel in response to the first communication unit comprising base layer data. 